CROSS-REFERENCE TO RELATED APPLICATION(S)
FIELD
[0002] Embodiments described herein relate generally to a semiconductor device.
BACKGROUND
[0003] Silicon carbide is expected as a material for next-generation semiconductor devices.
Silicon carbide has excellent physical properties such as an about 3 times larger
bandgap, an about 10 times stronger breakdown electric field strength, and an about
3 times higher thermal conductivity, as compared to silicon. By utilizing these properties,
for example, a metal oxide semiconductor field effect transistor (MOSFET) which is
operable at a high temperature with a high pressure resistance and a low loss may
be implemented.
[0004] A vertical MOSFET using silicon carbide has a pn junction diode as a body diode.
For example, the MOSFET is used as a switching element connected to an inductive load.
In this case, even when the MOSFET is OFF, a reflux current may be caused to flow
by using the body diode.
[0005] However, when the reflux current is caused to flow by using the body diode, a problem
occurs in that a stacking defect grows in the silicon carbide layer due to recombination
energy of carriers, and thus, the ON-resistance of the MOSFET increases. The increase
in ON-resistance of the MOSFET causes a degradation of the reliability of the MOSFET.
[0006] There is a MOSFET equipped with a Schottky barrier diode (SBD) that operates in a
unipolar manner. When the reflux current is caused to flow by using the SBD instead
of the pn junction diode that operates in a bipolar manner, the growth of stacking
defect is prevented. Thus, the reliability of the MOSFET is improved.
DESCRIPTION OF THE DRAWINGS
[0007]
FIG. 1 is a schematic top view illustrating a semiconductor device according to an
embodiment.
FIG. 2 is a schematic cross-sectional view of the semiconductor device according to
the embodiment.
FIG. 3 is an equivalent circuit diagram of the semiconductor device of the embodiment.
FIG. 4 is a schematic top view of a semiconductor device of a comparative example.
FIG. 5 is a view illustrating a problem of the semiconductor device of the comparative
example.
FIG. 6 is a view illustrating an operation and effects of the semiconductor device
according to the embodiment.
DETAILED DESCRIPTION
[0008] In general, according to one embodiment, a semiconductor device includes: an insulating
substrate; a first main terminal; a second main terminal; an output terminal; a first
metal layer formed on the insulating substrate, provided with a first connection region,
and electrically connected to the first main terminal in the first connection region;
a second metal layer formed on the insulating substrate, provided with a second connection
region, and electrically connected to the second main terminal in the second connection
region; a third metal layer formed on the insulating substrate to be disposed between
the first metal layer and the second metal layer, provided with a third connection
region, and electrically connected to the output terminal in the third connection
region; a plurality of first semiconductor chips each including a first upper electrode,
a first lower electrode, a first gate electrode, a first silicon carbide layer, and
a first Schottky barrier diode, and arranged in a first direction in a state where
the first lower electrode is electrically connected to the first metal layer; a plurality
of second semiconductor chips each including a second upper electrode, a second lower
electrode, a second gate electrode, a second silicon carbide layer, and a second Schottky
barrier diode, and arranged in the first direction in a state where the second lower
electrode is electrically connected to the third metal layer; a first connection wire
configured to electrically connect the first upper electrode and the third metal layer;
and a second connection wire configured to electrically connect the second upper electrode
and the second metal layer. The second semiconductor chips exist in a second direction
perpendicular to the first direction of the first semiconductor chips and parallel
to the insulating substrate. An angle formed by the third direction that connects
the first connection region and the second connection region, and the first direction
is 20° or less. An angle formed by an extension direction of the first connection
wire and the second direction is 20° or less. An angle formed by an extension direction
of the second connection wire connected to the second upper electrode of a second
semiconductor chip closest to the first metal layer in the first direction among the
plurality of second semiconductor chips, and the second direction is 20° or less.
[0009] In the descriptions herein, the same or similar members may be denoted by the same
reference numerals, and overlapping descriptions thereof may be omitted.
[0010] In the descriptions herein, in order to indicate the positional relationship of components
and others, the upward direction of each drawing may be described as "upper (above)",
and the downward direction of each drawing may be described as "lower (below)". In
the descriptions herein, the concepts of "upper" and "lower" do not necessarily indicate
the relationship with the direction of gravity.
[0011] A semiconductor device of an embodiment includes: an insulating substrate; a first
main terminal; a second main terminal; an output terminal; a first metal layer formed
on the insulating substrate, provided with a first connection region, and electrically
connected to the first main terminal in the first connection region; a second metal
layer formed on the insulating substrate, provided with a second connection region,
and electrically connected to the second main terminal in the second connection region;
a third metal layer formed on the insulating substrate to be disposed between the
first metal layer and the second metal layer, provided with a third connection region,
and electrically connected to the output terminal in the third connection region;
a plurality of first semiconductor chips each including a first upper electrode, a
first lower electrode, a first gate electrode, a first silicon carbide layer, and
a first Schottky barrier diode, and arranged in a first direction in a state where
the first lower electrode is electrically connected to the first metal layer; a plurality
of second semiconductor chips each including a second upper electrode, a second lower
electrode, a second gate electrode, a second silicon carbide layer, and a second Schottky
barrier diode, and arranged in the first direction in a state where the second lower
electrode is electrically connected to the third metal layer; a first connection wire
configured to electrically connect the first upper electrode and the third metal layer;
and a second connection wire configured to electrically connect the second upper electrode
and the second metal layer. The second semiconductor chips exist in a second direction
perpendicular to the first direction of the first semiconductor chips and parallel
to the insulating substrate. An angle formed by the third direction that connects
the first connection region and the second connection region, and the first direction
is 20° or less, and an angle formed by an extension direction of the first connection
wire and the second direction is 20° or less. An angle formed by an extension direction
of the second connection wire connected to the second upper electrode of a second
semiconductor chip closest to the first metal layer in the first direction among the
plurality of second semiconductor chips, and the second direction is 20° or less.
[0012] FIG. 1 is a schematic top view of a semiconductor device of an embodiment. FIG. 2
is a schematic cross-sectional view of the semiconductor device of the embodiment.
FIG. 2 represents the cross section along AA' of FIG. 1. FIG. 3 is an equivalent circuit
diagram of the semiconductor device of the embodiment.
[0013] The semiconductor device of the embodiment is a power semiconductor module 100. As
illustrated in FIG. 3, the power semiconductor module 100 of the embodiment is a so-called
"2 in 1" type module in which a half bridge circuit may be configured with one module.
In the power semiconductor module 100, three half bridge units are connected in parallel.
For example, a three-phase inverter circuit may be implemented by three power semiconductor
modules of the embodiment.
[0014] As illustrated in FIG. 3, the power semiconductor module 100 includes a positive
terminal P (a first main terminal), a negative terminal N (a second main terminal),
an AC output terminal AC (an output terminal), and multiple high-side MOSFETs 11 (first
semiconductor chips) and multiple low-side MOSFETs 21 (second semiconductor chips).
Each MOSFET is equipped with a Schottky barrier diode (SBD), in addition to a pn junction
diode. The SBD has, for example, a function of causing the flow of a reflux current.
[0015] The multiple high-side MOSFETs 11 are connected in parallel. The multiple low-side
MOSFETs 21 are connected in parallel. The multiple high-side MOSFETs 11 and the multiple
low-side MOSFETs 21 are connected in series.
[0016] FIGS. 1 to 3 illustrate a case where the number of high-side MOSFETs 11 is three,
and the number of low-side MOSFETs 21 is three.
[0017] As illustrated in FIGS. 1 and 2, the power semiconductor module 100 of the embodiment
is provided with the positive terminal P (the first main terminal), the negative terminal
N (the second main terminal), the AC output terminal AC (the output terminal), the
multiple high-side MOSFETs 11 (the first semiconductor chips), the multiple low-side
MOSFETs 21 (the second semiconductor chips), a resin housing 24, a lid 26, a metal
base 28, an insulating substrate 30, a first metal layer 31, and a second metal layer
32, a third metal layer 33, a first gate metal layer 36 (a fourth metal layer), a
second gate metal layer 37 (a fifth metal layer), a back-surface metal layer 40, a
first gate terminal 41, a second gate terminal 42, first bonding wires 44 (first connection
wires), second bonding wires 46 (second connection wires), gate bonding wires 48,
and a sealing resin 50.
[0018] Each of the multiple high-side MOSFETs 11 (the first semiconductor chips) includes
a first source electrode 11a (a first upper electrode), a first drain electrode 11b
(a first lower electrode), and a first gate electrode 11c, a first silicon carbide
layer 11x, and a first Schottky barrier diode 11y.
[0019] Each of the multiple low-side MOSFETs 21 (the second semiconductor chips) includes
a second source electrode 21a (a second upper electrode), a second drain electrode
21b (a second lower electrode), a second gate electrode 21c, a second silicon carbide
layer 21x, and a second Schottky barrier diode 21y.
[0020] The first metal layer 31 has a first connection region 31x. The second metal layer
32 has a second connection region 32x. The third metal layer 33 has a third connection
region 33x.
[0021] FIG. 1 is a top view of the power semiconductor module 100 in a state where the lid
26 and the sealing resin 50 are removed.
[0022] The metal base 28 is, for example, copper. For example, when the power semiconductor
module 100 is mounted on a product, a heat dissipation plate (not illustrated) is
connected to the back surface of the metal base 28.
[0023] The insulating substrate 30 is provided on the metal base 28. The insulating substrate
30 is provided between the metal base 28 and the high-side MOSFETs 11, and between
the metal base 28 and the low-side MOSFETs 21.
[0024] The insulating substrate 30 has a function of electrically separating the metal base
28 and the high-side MOSFETs 11, and the metal base 28 and the low-side MOSFETs 21.
[0025] The insulating substrate 30 is, for example, ceramic. The insulating substrate 30
is, for example, aluminum oxide, aluminum nitride, or silicon nitride.
[0026] The first metal layer 31, the second metal layer 32, the third metal layer 33, the
first gate metal layer 36, and the second gate metal layer 37 are formed on the surface
of the insulating substrate 30. The first metal layer 31, the second metal layer 32,
the third metal layer 33, the first gate metal layer 36, and the second gate metal
layer 37 are, for example, copper.
[0027] The back-surface metal layer 40 is formed on the back surface of the insulating substrate
30. The back-surface metal layer 40 is, for example, copper. The back-surface metal
layer 40 is joined to the metal base 28 by using, for example, a solder layer or a
silver nanoparticle layer (not illustrated).
[0028] The resin housing 24 is provided around the metal base 28 and the insulating substrate
30. A portion of the resin housing 24 is provided on the metal base 28. The resin
housing 24 has a function of protecting the high-side MOSFETs 11, the low-side MOSFETs
21, and the insulating substrate 30.
[0029] The lid 26 is provided on the resin housing 24. The lid 26 has a function of protecting
the high-side MOSFETs 11, the low-side MOSFETs 21, and the insulating substrate 30.
[0030] The multiple high-side MOSFETs 11 are provided on the first metal layer 31. Each
of the multiple high-side MOSFETs 11 includes the first source electrode 11a, the
first drain electrode 11b, the first gate electrode 11c, the first silicon carbide
layer 11x, and the first Schottky barrier diode 11y. The first source electrode 11a
is an example of the first upper electrode. The first drain electrode 11b is an example
of the first lower electrode.
[0031] The first source electrode 11a is electrically connected to the third metal layer
33. The first source electrode 11a and the third metal layer 33 are electrically connected
to each other, by using, for example, a first bonding wire 44. The first drain electrode
11b is electrically connected to the first metal layer 31. The first drain electrode
11b is electrically connected to the first metal layer 31 by using, for example, a
solder layer or a silver nanoparticle layer (not illustrated).
[0032] The multiple high-side MOSFETs 11 are arranged in a first direction parallel to the
insulating substrate 30.
[0033] The multiple low-side MOSFETs 21 are provided on the third metal layer 33. Each of
the multiple low-side MOSFETs 21 includes the second source electrode 21a, the second
drain electrode 21b, the second gate electrode 21c, the second silicon carbide layer
21x, and the second Schottky barrier diode 21y. The second source electrode 21a is
an example of the second upper electrode. The second drain electrode 21b is an example
of the second lower electrode.
[0034] The second source electrode 21a is electrically connected to the second metal layer
32. The second source electrode 21a and the second metal layer 32 are electrically
connected to each other, by using, for example, a second bonding wire 46. The second
drain electrode 21b is electrically connected to the third metal layer 33. The second
drain electrode 21b is electrically connected to the third metal layer 33 by using,
for example, a solder layer or a silver nanoparticle layer (not illustrated).
[0035] The multiple low-side MOSFETs 21 are arranged in the first direction parallel to
the insulating substrate 30.
[0036] The sealing resin 50 is filled in the resin housing 24. The sealing resin 50 is surrounded
by the resin housing 24. The sealing resin 50 covers the high-side MOSFETs 11, the
low-side MOSFETs 21, and the insulating substrate 30.
[0037] The sealing resin 50 has a function of protecting the high-side MOSFETs 11, the low-side
MOSFETs 21, and the insulating substrate 30. Further, the sealing resin 50 has a function
of insulating the high-side MOSFETs 11, the low-side MOSFETs 21, and the insulating
substrate 30 from each other.
[0038] The sealing resin 50 contains a resin. The sealing resin 50 is, for example, a silicon
gel. For the sealing resin 50, for example, an epoxy resin, a polyimide resin or other
resins may be applied.
[0039] The positive terminal P is provided on one end side of the insulating substrate 30.
For example, in FIG. 1, the positive terminal P is provided on the right side of the
insulating substrate 30. The positive terminal P has a wiring connection hole.
[0040] The positive terminal P is electrically connected to the first metal layer 31 in
the first connection region 31x. In the first connection region 31x, the first metal
layer 31 and the positive terminal P are connected to each other by using, for example,
a solder layer or a silver nanoparticle layer (not illustrated).
[0041] For example, a positive voltage is applied to the positive terminal P from the outside.
The positive terminal P is made of a metal. The positive terminal P is, for example,
copper.
[0042] The negative terminal N is provided on one end side of the insulating substrate 30.
The negative terminal N is provided on the same side of the insulating substrate 30
as the side thereof on which the positive terminal P is provided. The negative terminal
N has a wiring connection hole.
[0043] The negative terminal N is electrically connected to the second metal layer 32 in
the second connection region 32x. In the second connection region 32x, the second
metal layer 32 and the negative terminal N are connected to each other by using, for
example, a solder layer or a silver nanoparticle layer (not illustrated).
[0044] For example, a negative voltage is applied to the negative terminal N from the outside.
The negative terminal N is made of a metal. The negative terminal N is, for example,
copper.
[0045] The AC output terminal AC is provided on one end side of the insulating substrate
30. The AC output terminal AC is provided on the same side of the insulating substrate
30 as the side thereof on which the positive terminal P and the negative terminal
N are provided. The AC output terminal AC has a wiring connection hole.
[0046] The AC output terminal AC is electrically connected to the third metal layer 33 in
the third connection region 33x. In the third connection region 33x, the third metal
layer 33 and the AC output terminal AC are connected to each other by using, for example,
a solder layer or a silver nanoparticle layer (not illustrated).
[0047] The AC output terminal AC outputs output currents of the half bridge circuits. The
AC output terminal AC is made of a metal. The AC output terminal AC is, for example,
copper.
[0048] The first gate terminal 41 is electrically connected to the first gate electrodes
11c of the high-side MOSFETs 11. The first gate terminal 41 is electrically connected
to the first gate electrodes 11c by using, for example, the first gate metal layer
36 and a gate bonding wire 48.
[0049] The second gate terminal 42 is electrically connected to the second gate electrodes
21c of the low-side MOSFETs 21. The second gate terminal 42 is electrically connected
to the second gate electrodes 21c by using, for example, the second gate metal layer
37 and a gate bonding wire 48.
[0050] The first metal layer 31 is formed on the insulating substrate 30. The first metal
layer 31 has the first connection region 31x. The first metal layer 31 is electrically
connected to the positive terminal P in the first connection region 31x.
[0051] The second metal layer 32 is formed on the insulating substrate 30. The second metal
layer 32 has the second connection region 32x. The second metal layer 32 is electrically
connected to the negative terminal N in the second connection region 32x. The second
metal layer 32 is electrically connected to the second source electrodes 21a of the
low-side MOSFETs 21.
[0052] The third metal layer 33 is formed on the insulating substrate 30. The third metal
layer 33 includes the third connection region 33x. The third metal layer 33 is electrically
connected to the AC output terminal AC in the third connection region 33x. The third
metal layer 33 is electrically connected to the first source electrodes 11a of the
high-side MOSFETs 11.
[0053] A respective one of the multiple low-side MOSFETs 21 exists in a second direction
perpendicular to the first direction and parallel to the insulating substrate 30,
for each of the multiple high-side MOSFETs 11. In other words, each high-side MOSFET
11 is provided adjacent to each low-side MOSFET 21 in the second direction.
[0054] The direction that connects the first connection region 31x and the second connection
region 32x to each other is defined as a third direction. The third direction is the
direction of the segment that connects the first connection region 31x and the second
connection region 32x with the shortest distance. The angle formed by the third direction
and the first direction is 20° or less.
[0055] For example, in FIG. 1, the third direction is parallel to the first direction. The
angle formed by the third direction and the first direction is 0°. Thus, the multiple
high-side MOSFETs 11 are arranged in the third direction. Further, the multiple low-side
MOSFETs 21 are arranged in the third direction.
[0056] The angle formed by the extension direction of the first bonding wire 44 and the
second direction is 20° or less. For example, when multiple first bonding wires 44
are connected to one high-side MOSFET 11, the angle formed by the extension direction
of at least one of the multiple first bonding wires 44 and the second direction is
20° or less. The angle formed by the extension direction of the first bonding wire
44 connected to any one of the multiple high-side MOSFETs 11 and the second direction
is 20° or less.
[0057] The angle formed by the extension direction of the first bonding wire 44 and the
third direction is 70° or more and 90° or less. For example, when multiple first bonding
wires 44 are connected to one high-side MOSFET 11, the angle formed by the extension
direction of at least one of the multiple first bonding wires 44 and the third direction
is 70° or more and 90° or less. The angle formed by the extension direction of the
first bonding wire 44 connected to any one of the multiple high-side MOSFETs 11 and
the third direction is 70° or more and 90° or less.
[0058] Further, the extension direction of the first bonding wire 44 is, for example, the
direction of the segment that connects the position where the first bonding wire 44
is in contact with the first source electrode 11a and the position where the first
bonding wire 44 is in contact with the third metal layer 33.
[0059] For example, the angle formed by the extension directions of all of the first bonding
wires 44 provided in the semiconductor module 100 and the second direction is 20°
or less. FIG. 1 represents a case where the angle formed by the extension directions
of all of the first bonding wires 44 provided in the semiconductor module 100 and
the second direction is 0°.
[0060] The angle formed by the extension direction of the second bonding wire 46 and the
second direction is 20° or less. For example, when multiple second bonding wires 46
are connected to one low-side MOSFET 21, the angle formed by the extension direction
of at least one of the multiple second bonding wires 46 and the second direction is
20° or less. The angle formed by the extension direction of the second bonding wire
46 connected to any one of the multiple low-side MOSFETs 21 and the second direction
is 20° or less.
[0061] The angle formed by the extension direction of the second bonding wire 46 connected
to the second source electrode 21a of the low-side MOSFET 21 closest to the first
metal layer 31 in the first direction, among the multiple low-side MISFETs 21, and
the second direction is 20° or less. That is, in FIG. 1, the angle formed by the extension
direction of the second bonding wire 46 connected to the second source electrode 21a
of the low-side MOSFET 21 at the lowest side, among the multiple low-side MOSFETs
21, and the second direction is 20° or less.
[0062] The angle formed by the extension direction of the second bonding wire 46 and the
third direction is 70° or more and 90° or less. For example, when multiple second
bonding wires 46 are connected to one low-side MOSFET 21, the angle formed by the
extension direction of at least one of the multiple second bonding wires 46 and the
third extension direction is 70° or more and 90° or less. The angle formed by the
extension direction of the second bonding wire 46 connected to any one of the multiple
low-side MOSFETs 21 and the third direction is 70° or more and 90° or less.
[0063] Further, the extension direction of the second bonding wire 46 is, for example, the
direction of the segment that connects the position where the second bonding wire
46 is in contact with the second source electrode 21a and the position where the second
bonding wire 46 is in contact with the second metal layer 32.
[0064] For example, the angle formed by the extension directions of all of the second bonding
wires 46 provided in the semiconductor module 100 and the second direction is 20°
or less. FIG. 1 represents a case where the extension directions of all of the second
bonding wires 46 provided in the semiconductor module 100 and the second direction
is 0°.
[0065] For example, the second metal layer 32 exists in the second direction of the low-side
MOSFET 21 closest to the first metal layer 31 in the first direction, among the multiple
low-side MOSFETs 21. That is, in FIG. 1, the second metal layer 32 exists in the second
direction of the low-side MOSFET 21 at the lowest side, among the multiple low-side
MOSFETs 21.
[0066] For example, the second metal layer 32 exists in the second direction of the contact
points between the second source electrode 21a of the low-side MOSFET 21 closest to
the first metal layer 31 in the first direction (C1 and C2 in FIG. 1), among the multiple
low-side MOSFETs 21, and the second bonding wires 46. For example, of the contact
points between the second source electrode 21a of the low-side MOSFET 21 closest to
the first metal layer 31 in the first direction among the multiple low-side MOSFETs
21, and the second bonding wires 46, the second metal layer 32 exists in the second
direction of the contact point closest to the first metal layer 31 (C2 in FIG. 1).
[0067] For example, the second metal layer 32 exists in the second direction of the end
of the low-side MOSFET 21 closest to the first metal layer 31 in the first direction,
the end which is close to the first metal layer 31 (E1 in FIG. 1).
[0068] For example, a first distance in the first direction between the second connection
region 32x and the end of the second metal layer 32 close to the first metal layer
31 (d1 in FIG. 1) is larger than a second distance in the first direction between
the end of the low-side MOSFET 21 closest to the first metal layer 31 in the first
direction among the multiple low-side MOSFETs 21, the end which is away from the first
metal layer 31, and the end of the second metal layer 32 close to the first metal
layer 31 (d2 in FIG. 1).
[0069] For example, the first distance in the first direction between the second connection
region 32x and the end of the second metal layer 32 close to the first metal layer
31 (d1 in FIG. 1) is larger than a third distance in the first direction between the
second connection region 32x and the end of the second metal layer 32 which is opposite
to the first metal layer 31 (d3 in FIG. 1).
[0070] Next, the operation and effects of the semiconductor device of the embodiment will
be described.
[0071] A vertical MOSFET using silicon carbide has the pn junction diode as a body diode.
For example, the MOSFET is used as a switching element connected to an inductive load.
In this case, even when the MOSFET is OFF, a reflux current may be caused to flow
by using the body diode.
[0072] However, when the reflux current is caused to flow by using the body diode, a problem
occurs in that a stacking defect grows in the silicon carbide layer due to recombination
energy of carriers, and thus, the ON-resistance of the MOSFET increases. The increase
in ON-resistance of the MOSFET causes a degradation in reliability of the MOSFET.
[0073] There is a MOSFET equipped with a Schottky barrier diode (SBD) that operates in a
unipolar form. When the reflux current is caused to flow by using the SBD instead
of the pn junction diode that operates in a bipolar form, the growth of a stacking
defect is prevented. Thus, the reliability of the MOSFET is improved.
[0074] In a power semiconductor module including multiple MOSFETs each equipped with an
SBD, it also becomes important to prevent the operation of the pn junction diode of
each MOSFET, from the viewpoint of improving the reliability of the power semiconductor
module.
[0075] FIG. 4 is a schematic top view of a semiconductor device of a comparative example.
The semiconductor device of the comparative example is a power semiconductor module
900. The equivalent circuit diagram of the power semiconductor module 900 is the same
as illustrated in FIG.3.
[0076] As illustrated in FIG. 4, the power semiconductor module 900 is different from the
power semiconductor module 100 of the embodiment in that the first direction in which
the multiple high-side MOSFETs 11 are arranged is perpendicular to the third direction.
Further, the power semiconductor module 900 is different from the power semiconductor
module 100 of the embodiment in that the first direction in which the multiple low-side
MOSFETs 21 are arranged is perpendicular to the third direction. The third direction
is the direction that connects the first connection region 31x and the second connection
region 32x.
[0077] Further, as illustrated in FIG. 4, the power semiconductor module 900 is different
from the power semiconductor module 100 of the embodiment in that the angle formed
by the extension direction of the first bonding wire 44 and the third direction is
parallel. Further, as illustrated in FIG. 4, the power semiconductor module 900 is
different from the power semiconductor module 100 of the embodiment in that the angle
formed by the extension direction of the second bonding wire 46 and the third direction
is parallel.
[0078] It has been identified that during the switching operation of the power semiconductor
module 900, a variation occurs in the currents flowing through the diodes provided
in the multiple high-side MOSFETs 11 or the diodes provided in the multiple low-side
MOSFETs 21. Further, it has been identified that when the variation of the currents
flowing through the diodes becomes large, the pn junction diode may operate by exceeding
the amount of current that may be caused to flow by the Schottky barrier diode.
[0079] FIG. 5 is a view illustrating the problem of the semiconductor device of the comparative
example. FIG. 5 is a schematic top view of the power semiconductor module 900.
[0080] FIG. 5 represents three routes from the positive terminal P to the negative terminal
N through the MOSFETs, that is, routes X9, Y9, and Z9 by dashed arrows. The routes
X9, Y9, and Z9 are routes from the first connection region 31x to the second connection
region 32x.
[0081] As a result of the examination by the inventors, it has been identified that the
variation of the currents flowing through the diodes during the switching operation
of the power semiconductor module 900 depends on the variation of the lengths of the
routes X9, Y9, and Z9.
[0082] For example, among the three routes, the route X9 is the shortest route, and the
route Z9 is the longest route. The current flowing through the diodes of the MOSFETs
existing in the route X9, which is the shortest route, is the largest. Further, the
current flowing through the diodes of the MOSFETs existing in the route Z9, which
is the longest route, is the smallest.
[0083] For example, it may be considered that the power semiconductor module 900 is connected
to an external inductive load, the multiple high-side MOSFETs 11 are in an OFF state,
and the multiple low-side MOSFETs 21 are in an ON state in which the current flows.
From this state, the multiple high-side MOSFETs 11 are switched to the ON state, and
the multiple low-side MOSFETs 21 are switched to the OFF state. At this time, the
multiple low-side MOSFETs 21 enter a reverse conduction state, and a reflux current
flows through the diodes equipped in the low-side MOSFETs 21.
[0084] At this time, the current flowing through the diodes of the low-side MOSFETs 21 existing
in the route X9, which is the shortest route, becomes the largest. Further, the current
flowing through the diodes of the low-side MOSFETs 21 existing in the route Z9 which
is the longest route, becomes the smallest.
[0085] When the reflux current flowing through the diodes of the low-side MOSFETs 21 existing
in the route X9 exceeds an allowable current range of a second Schottky barrier diode
21y provided in the low-side MOSFET 21, the pn junction diode operates. When the pn
junction diode operates, the reliability of the low-side MOSFETs 21 existing in the
route X9 is degraded. Then, the reliability of the power semiconductor module 900
is degraded.
[0086] FIG. 6 is a view illustrating the operation and effects of the semiconductor device
of the embodiment. FIG. 6 is a schematic top view of the power semiconductor module
100.
[0087] FIG. 6 represents three routes from the positive terminal P to the negative terminal
N through the MOSFETs, that is, routes X1, Y1, and Z1 by dashed arrows. The routes
X1, Y1, and Z1 are routes from the first connection region 31x to the second connection
region 32x.
[0088] The power semiconductor module 100 of the first embodiment reduces the variation
of the lengths of the routes X1, Y1, and Z1 by changing the arrangement direction
of the MOSFETs and the extension direction of the bonding wires, as compared with
the power semiconductor module 900 of the comparative example.
[0089] Specifically, the multiple high-side MOSFETs 11 are arranged along the third direction
that connects the first connection region 31x and the second connection region 32x.
The multiple low-side MOSFETs 21 are also arranged along the third direction. The
angle formed by the third direction and the first direction in which the multiple
high-side MOSFETs 11 and the multiple low-side MOSFETs 21 are arranged is 20° or less.
[0090] Further, the angle formed by the extension direction of the first bonding wire 44
and the second direction is 20° or less. The angle formed by the extension direction
of the second bonding wire 46 and the second direction is 20° or less.
[0091] With the configuration described above, the power semiconductor module 100 of the
embodiment reduces the variation of the lengths of the routes X1, Y1, and Z1. Thus,
the variation of the currents flowing through the diodes during the switching operation
of the power semiconductor module 100 is reduced. Accordingly, the operation of the
pn junction diode provided in each MOSFET is prevented. As a result, the reliability
of the power semiconductor module 100 is improved.
[0092] The angle formed by the third direction and the first direction in which the multiple
high-side MOSFETs 11 and the multiple low-side MOSFETs 21 are arranged is preferably
10° or less, more preferably 5° or less, and most preferably 0°. As the angle becomes
smaller, the variation of the lengths of the routes X1, Y1, and Z1 is further reduced.
[0093] Further, the angle formed by the extension directions of all of the first bonding
wires 44 provided in the semiconductor module 100 and the second direction is preferably
20° or less. Further, the angle formed by the extension directions of all of the second
bonding wires 46 provided in the semiconductor module 100 and the second direction
is preferably 20° or less. With this configuration, the variation of the lengths of
the routes X1, Y1, and Z1 is further reduced.
[0094] Further, the angle formed by the extension direction of the first bonding wire 44
and the second direction is preferably 10° or less, more preferably 5° or less, and
most preferably 0°. The angle formed by the extension direction of the second bonding
wire 46 and the second direction is preferably 10° or less, more preferably 5° or
less, and most preferably 0°. As the angle becomes smaller, the variation of the lengths
of the routes X1, Y1, and Z1 is further reduced.
[0095] It is preferable that the second metal layer 32 exists in the second direction of
the low-side MOSFET 21 closest to the first metal layer 31 in the first direction,
among the multiple low-side MOSFETs 21. That is, in FIG. 1, it is preferable that
the second metal layer 32 exists in the second direction of the low-side MOSFET 21
at the lowest side among the multiple low-side MOSFETs 21. With this configuration,
the variation of the lengths of the routes X1, Y1, and Z1 is further reduced.
[0096] It is preferable that the second metal layer 32 exists in the second direction of
the contact points between the second source electrode 21a of the low-side MOSFET
21 closest to the first metal layer 31 in the first direction (C1 and C2 in FIG. 1),
among the multiple low-side MOSFETs 21, and the second bonding wires 46. It is preferable
that, of the contact points between the second source electrode 21a of the low-side
MOSFET 21 closest to the first metal layer 31 in the first direction among the multiple
low-side MOSFETs 21, and the second bonding wires 46, the second metal layer 32 exists
in the second direction of the contact point closest to the first metal layer 31 (C2
in FIG. 1). With this configuration, the variation of the lengths of the routes X1,
Y1, and Z1 is further reduced.
[0097] It is preferable that the second metal layer 32 exists in the second direction of
the end of the low-side MOSFET 21 closest to the first metal layer 31 in the first
direction among the multiple low-side MOSFETs 21, the end which is close to the first
metal layer 31 (E1 in FIG. 1). With this configuration, the variation of the lengths
of the routes X1, Y1, and Z1 is further reduced.
[0098] It is preferable that the first distance in the first direction between the second
connection region 32x and the end of the second metal layer 32 close to the first
metal layer 31 (d1 in FIG. 1) is larger than the second distance in the first direction
between the end of the low-side MOSFET 21 closest to the first metal layer 31 in the
first direction among the multiple low-side MOSFETs 21, the end which is away from
the first metal layer 31, and the end of the second metal layer 32 close to the first
metal layer 31 (d2 in FIG. 1). With this configuration, the variation of the lengths
of the routes X1, Y1, and Z1 is further reduced.
[0099] It is preferable that the first distance in the first direction between the second
connection region 32x and the end of the second metal layer 32 close to the first
metal layer 31 (d1 in FIG. 1) is larger than the third distance in the first direction
between the second connection region 32x and the end of the second metal layer 32
which is opposite to the first metal layer 31 (d3 in FIG. 1). With this configuration,
the variation of the lengths of the routes X1, Y1, and Z1 is further reduced.
[0100] In the embodiment, descriptions are made on a case where the number of power semiconductor
chips arranged in parallel is three, as an example. The number of power semiconductor
chips may be two or four or more.
[0101] In the embodiment, descriptions are made on a case where the power semiconductor
module is a "2 in 1" type module, as an example. The power semiconductor module may
have other circuit configurations such as, for example, a "4 in 1" type module and
a "6 in 1" type module.
[0102] The first and second bonding wires may be linear bonding wires or ribbon-shaped bonding
wires. Further, the first and second bonding wires may be, for example, plate-shaped
conductors if the conductors have the function of performing an electric connection.
[0103] In the embodiment, descriptions are made on a case where a portion of the terminal
such as the positive terminal P or the like is directly connected to the metal layer,
as an example. The terminal and the metal layer may be connected by, for example,
a bonding wire.
[0104] In the embodiment, descriptions are made on a case where the positive terminal, the
negative terminal, and the AC output terminal are all provided at the same end of
the power semiconductor module, as an example. The arrangement positions of the positive
terminal, the negative terminal, and the AC output terminal are not limited to the
arrangement positions described above.
[0105] While certain embodiments have been described, these embodiments have been presented
by way of example only, and are not intended to limit the scope of the disclosure.
Indeed, the novel embodiments described herein may be embodied in a variety of other
forms; furthermore, various omissions, substitutions and changes in the form of the
embodiments described herein may be made without departing from the spirit of the
disclosure. The accompanying claims and their equivalents are intended to cover such
forms or modifications as would fall within the scope and spirit of the disclosure.
[0106] It is explicitly stated that all features disclosed in the description and/or the
claims are intended to be disclosed separately and independently from each other for
the purpose of original disclosure as well as for the purpose of restricting the claimed
invention independent of the composition of the features in the embodiments and/or
the claims. It is explicitly stated that all value ranges or indications of groups
of entities disclose every possible intermediate value or intermediate entity for
the purpose of original disclosure as well as for the purpose of restricting the claimed
invention, in particular as limits of value ranges.
1. A semiconductor device (100) comprising:
an insulating substrate (30);
a first main terminal (P);
a second main terminal (N);
an output terminal (AC);
a first metal layer (31) provided on the insulating substrate (30), the first metal
layer (31) including a first connection region (31x), and the first metal layer (31)
electrically connected to the first main terminal (P) in the first connection region
(31x);
a second metal layer (32) provided on the insulating substrate (30), the second metal
layer (32) including a second connection region (32x), and the second metal layer
(32) electrically connected to the second main terminal (N) in the second connection
region (32x);
a third metal layer (33) provided on the insulating substrate (30), the third metal
layer (33) disposed between the first metal layer (31) and the second metal layer
(32), the third metal layer (33) including a third connection region (33x), and the
third metal layer (33) electrically connected to the output terminal (AC) in the third
connection region(33x);
a plurality of first semiconductor chips (11) each including a first upper electrode
(11a), a first lower electrode (11b), a first gate electrode (11c), a first silicon
carbide layer (11x), and a first Schottky barrier diode (11y), and the plurality of
the first semiconductor chips (11) arranged in a first direction, and the first lower
electrode (11b) being electrically connected to the first metal layer (31);
a plurality of second semiconductor chips (21) each including a second upper electrode
(21a), a second lower electrode (21b), a second gate electrode (21c), a second silicon
carbide layer (21x), and a second Schottky barrier diode (21y), and the plurality
of the second semiconductor chips (21) arranged in the first direction, and the second
lower electrode (21b) is electrically connected to the third metal layer (33);
a first connection wire (44) electrically connecting the first upper electrode (11a)
and the third metal layer (33); and
a second connection wire (46) electrically connecting the second upper electrode (21a)
and the second metal layer (32),
wherein the second semiconductor chips (21) exist in a second direction of the first
semiconductor chips (11), the second direction is perpendicular to the first direction
and parallel to the insulating substrate (30),
an angle formed by a third direction and the first direction is 20° or less, the third
direction connects the first connection region (31x) and the second connection region
(32x), and
an angle formed by an extension direction of the second connection wire (46) connected
to the second upper electrode (21a) of one of the plurality of the second semiconductor
chips (21) and the second direction is 20° or less, the one of the plurality of the
second semiconductor chips (21) is closest to the first metal layer (31) in the first
direction among the plurality of the second semiconductor chips (21).
2. The semiconductor device (100) according to claim 1, wherein the second metal layer
(32) exists in the second direction of the one of the plurality of the second semiconductor
chips (21).
3. The semiconductor device (100) according to claim 1 or 2, wherein the second metal
layer (32) exists in the second direction of a contact point (C1, C2), and the second
upper electrode (21a) of the one of the plurality of the second semiconductor chips
(21) and the second connection wire (46) contact at the contact point (C1, C2).
4. The semiconductor device (100) according to claim 1 or 2, wherein the second metal
layer (32) exists in the second direction of an end (E1) of the one of the plurality
of the second semiconductor chips (21), the end (E1) is an end close to the first
metal layer (31).
5. The semiconductor device (100) according to claim 1 or 2, wherein a first distance
(d1) is larger than a second distance (d2), the first distance (d1) is a distance
in the first direction between the second connection region (32x) and a first end
of the second metal layer (32) close to the first metal layer (31), the second distance
(d2) is a distance in the first direction between a second end of the one of the plurality
of the second semiconductor chips (21) and the first end, and the second end is an
end away from the first metal layer (31).
6. The semiconductor device (100) according to claim 1 or 2, wherein a first distance
(d1) is larger than a third distance (d3), the first distance (d1) is a distance in
the first direction between the second connection region (32x) and a first end of
the second metal layer (32) close to the first metal layer (31), the third distance
(d3) is a distance in the first direction between the second connection region (32x)
and an end of the second metal layer (32) opposite to the first metal layer (31).
7. The semiconductor device (100) according to claim 1 or 2, further comprising:
a fourth metal layer (36) provided on the insulating substrate (30), the fourth metal
layer (36) disposed between the first metal layer (31) and the third metal layer (33),
and the fourth metal layer (36) is electrically connected to the first gate electrode
(11c); and
a fifth metal layer (37) provided on the insulating substrate (30), the fifth metal
layer (37) disposed between the second metal layer (32) and the third metal layer
(33), and the fifth metal layer (37) is electrically connected to the second gate
electrode (21c).
8. The semiconductor device (100) according to claim 1 or 2, wherein an angle formed
by an extension direction of the first connection wire (44) and the second direction
is 20° or less.